A Robust Encoding Scheme for Delivering Artificial Sensory Information via Direct Brain Stimulation

Bjånes, David A.; Moritz, Chet T.

doi:10.1109/tnsre.2019.2936739

Cited by 14 publications

(11 citation statements)

References 58 publications

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“…Our results on behavioral sensitivity to detection of sensation in rodents and primates were comparable to those observed with Intracortical Microstimulation (ICMS) of S1 (5,17). Notably, sensitivity to stimulus amplitude increased with increasing pulse width, frequency, and duration of stimulation.…”

Section: Discussionsupporting

confidence: 83%

“…Frequency modulation has been historically considered a promising method for providing sensory feedback with several studies showing that animals are capable of discriminating ICMS frequencies and that frequency modulation obeys Weber's law. (4,(20)(21)(22), While ICMS amplitude modulation in monkeys failed to follow Weber's law (5), experiments in rats showed that modulation of perceived intensity by amplitude and pulse-width modulation followed Weber's law (17). In our study, we investigated whether rats and monkeys could learn to discriminate SCS frequencies.…”

Section: Discussionmentioning

confidence: 96%

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Generating artificial sensations with spinal cord stimulation in primates and rodents

Yadav

Krucoff

et al. 2021

Brain Stimulation

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Section: Discussionsupporting

confidence: 83%

Section: Discussionmentioning

confidence: 96%

Generating artificial sensations with spinal cord stimulation in primates and rodents

Yadav

Krucoff

et al. 2021

Brain Stimulation

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“…Intra-cortical micro-stimulation (ICMS) patterns were generated using four key parameters [59]: pulse amplitude, pulse-width, stimulation frequency and total stimulation duration (Figure 1C). Pulse-amplitude ranged from 1-100µA, pulse-width from 44-400µsec, while the stimulation frequency was fixed at 300Hz and duration lasted up to 1s.…”

Section: Methodsmentioning

confidence: 99%

“…Previous studies have suggested electrical charge as a powerful modulator of somatosensory sensations in single-channel ICMS [28], [59], [60]. Specific spatial patterns of charge, delivered over multiple ICMS channels, may be an important parameter for targeting specific percepts or somatotopic locations [34] [39].…”

Section: Spatial Patterns Of Icms Analyze Role Of Charge In Evoked So...mentioning

confidence: 99%

Multi-channel intra-cortical micro-stimulation yields quick reaction times and evokes natural somatosensations in a human participant

Bjånes

Bashford

Pejsa

et al. 2022

Preprint

Self Cite

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Somatosensory brain-machine-interfaces (BMIs) can create naturalistic sensations by modulating activity of neural populations in the brain. By utilizing different spatial or temporal patterns of intra-cortical micro-stimulation (ICMS) in primary sensory cortex (S1), human patients suffering somatosensory loss can experience both cutaneous and proprioceptive sensory feedback. As evidenced by motor deficits in deafferented patients, rapid somatosensory feedback is critical for dexterous motor ability, in part because visual feedback is much slower than naturally occurring somatosensory input. However, somatosensory BMI studies typically report significantly longer cognitive processing latencies for cortical electrical stimulation than for naturally occurring somatosensations or visual sensations. In this study, we show that multi-channel electrical stimulation patterns elicit naturalistic somatosensory percepts in a human tetraplegic participant. Crucially, somatosensations evoked by multi-channel ICMS are cognitively processed at comparable latencies to naturally evoked sensations and significantly faster than visual sensations, as measured via a simple reaction time test. Further investigation demonstrated multi-channel stimulation could significantly reduce minimum amplitude detection thresholds and such reductions in charge density resulted in more frequent natural sensation descriptors reported by the human participant. Multi-channel ICMS patterns also evoked percepts with highly stable somatotopic locations. While some single-channel ICMS patterns evoked sensations 20-80% of the time, most multi-channel patterns could evoke sensations with 100% repeatability, an important step in demonstrating BCI device reliability. These improvements are all significant advances towards state-of-the-art sensory BMIs. The addition of such low-latency artificial sensory feedback to motor BMIs is expected to improve movement accuracy and increase embodiment for human users.

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“…tingling, as reported by the users [2]- [4], [6]- [11]. However, different groups approach this problem from different angles with marked differences in the site in the nervous system where the stimulation is delivered: central [12]- [14] vs. peripheral nervous system [2], [15]- [17]; invasive [2], [7], [8], [10], [18] vs. non-invasive [5], [17], [19]; and the way the neural stimulation is modulated to convey sensory precepts: biomimetic [8]- [10], [20]- [23] vs. abstract [13], [17], [21], [24]. We believe that this diversity is due to three main reasons: 1. uncertainty on how to best sense and convert sensory information from the environment to electrical patterns to stimulate the nervous system and evoke naturalistic sensation; 2. lack of technologies for targeted delivery of this information to the nervous system; and 3. research still ongoing on the development of biocompatible neural interfaces that allow direct communication with the peripheral nervous system without causing physical damage and pain.…”

mentioning

confidence: 99%

W:Ti Flexible Transversal Electrode Array for Peripheral Nerve Stimulation: A Feasibility Study

Silveira

Brunton

Escobedo-Cousin

et al. 2020

IEEE Trans. Neural Syst. Rehabil. Eng.

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The development of hardware for neural interfacing remains a technical challenge. We introduce a flexible, transversal intraneural tungsten:titanium electrode array for acute studies. We characterize the electrochemical properties of this new combination of tungsten and titanium using cyclic voltammetry and electrochemical impedance spectroscopy. With an in-vivo rodent study, we show that the stimulation of peripheral nerves with this electrode array is possible and that more than half of the electrode contacts can yield a stimulation selectivity index of 0.75 or higher at low stimulation currents. This feasibility study paves the way for the development of future cost-effective and easy-to-fabricate neural interfacing electrodes for acute settings, which ultimately can inform the development of technologies that enable bi-directional communication with the human nervous system.

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A Robust Encoding Scheme for Delivering Artificial Sensory Information via Direct Brain Stimulation

Cited by 14 publications

References 58 publications

Generating artificial sensations with spinal cord stimulation in primates and rodents

Generating artificial sensations with spinal cord stimulation in primates and rodents

Multi-channel intra-cortical micro-stimulation yields quick reaction times and evokes natural somatosensations in a human participant

W:Ti Flexible Transversal Electrode Array for Peripheral Nerve Stimulation: A Feasibility Study

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